1. APEC Climate Center (APCC) Climate Outlook for AMJ 2010
Presented by : R. H. Kripalani
Investigators : Soo-Jin Sohn, Young-Mi Min

2. Asia Pacific Economic Cooperation (APEC)
To meet the Bogor Goals of free and open trade
and investment in the Asia-Pacific region
Trade and Investment Liberalization
Business Facilitation
Economic and Technical Cooperation

3. Procedure of Seasonal Forecast
Participating
Institutions
APEC Member
Economics
APEC Climate Center (APCC)
MME Seasonal Production
Data
Collection
Quality
Check
Decision on
the official
APCC forecasts
Deterministic
Forecasts
(4 DMMEs)
Probabilistic
Forecast
(PMME)
17 models
Hindcast
Forecast
Historical
Observation
Communication
with
model holders
Outlook
Verification
(Previous forecast, Hindcast)
Graphics
(Individual models, DMMEs,
PMME, verification)
Dissemination
Decision on
the model set
Pre-
processing
Application
(Index forecast,
statistical downscaling)
10th
15th
20th

4. Participating Institutes
Member Economies
Acronym
Organization
Model Resolution
Australia
POAMA
Bureau of Meteorology Research Centre 
T47L17
Canada
MSC
Meteorological Service of Canada
1.875    L50
China
NCC
National Climate Center/CMA
T63L16
IAP
Institute of Atmospheric Physics
4   5  L2
Chinese Taipei
CWB
Central Weather Bureau
T42L18
Japan
JMA
Japan Meteorological Agency
T63L40
Korea
PNU
Pusan National University
GDAPS/KMA
Korea Meteorological Administration
T106L21
GCPS/SNU
Seoul National University
T63L21
METRI/KMA
Meteorological Research Institute
4   5  L17
Russia
MGO
Main Geophysical Observatory
T42L14
HMC
Hydrometeorological Centre of Russia
1.12   1.4  L28
Peru
SENAMHI
El Servicio Nacional de Meteorología e Hidrología
2.8   2.8 L18 
USA
IRI
COLA
International Research Institute
Center for Ocean-Land-Atmosphere Studies
T42L19
T63L18
NCEP
NCEP Coupled Forecast System
T62L64
NSIPP/NASA
National Aeronautics and Space Administration
2   2.5  L34

5. Participating Models Model Initialization Ensemble Size
SST Specification
Experimental Type
CWB
(Chinese Taipei)
GDAS from NCEP, date: 12Z from to (for the 2010JFM case) 10
OPGSST 1.1 from CWB
SMIP/HFP
GDAPS_F
(Korea)
NCEP RA2 (Time lagged initial condition – 3-7th 00Z, 06Z, 12Z, 18Z) 20
Forecasted SST
MSC_GM2
(Canada)
LAF approach with a 12 hour lag
Persistence of CMC analysis SST anomaly of the 30 days prior of the start of the runs
SMIP2/HFP
MSC_GM3
MSC_SEF
NCEP
(USA)
0Z, January 1-15, 2010, once a day (for the 2010MAM case) 15
Predicted
CMIP
NIMR
0000UTC 26th Apr. 2004, 12 hour time lag ( for the 2004JJA case)
OISST Apr anomaly + climate SST (Persistent)
POAMA
(Australia)
Atmosphere/Land reanalysis from AMIP run nudging 3D atmosphere to Bureau GASP
30, one day lag in initial time between each
Predicted, temperature assimilated using Optimum interpolation (Smith et al 1991) into top 500m of ocean every 3 days
CMIP,
coupled 1-tier

6. Simple Composite Method : Synthetic Multi-Model Super Ensemble Method:
Methodology: Deterministic MME Schemes
Simple Composite Method :
SCM
Simple composite of individual forecast with equal weighting.
Step-wise Pattern Projection Method :
Simple composite of individual forecasts, after
correction by statistical downscaling using SPPM.
SPM
Multiple Regression Method:
Optimally weighted composite of individual forecasts.
The weighting coefficient is obtained by SVD based
regression.
MRG
Synthetic Multi-Model Super Ensemble Method:
SSE
Weighted combination of statistically corrected multi model output.

7. 2010 AMJ Forecast (PREC)

8. 2010 AMJ Forecast (T850)

9. Updated Participating Models in MME
Initialization
Ensemble Size
SST Specification
Experimental Type
GCPS (Korea)
6hr interval from 7th to previous 12
predicted SST by KMA/SNU global SST prediction system
SMIP/HFP
JMA (Japan)
BGM method (9 members) and 5-day LAF, the latest is on 12th March,2010 (in case of 2010AMJ) 51
Forecasted SST
CMIP
* GCPS: Global Climate Prediction System

10. 2010 AMJ Forecast (PREC)

11. 2010 AMJ Forecast (T850)

12. Hindcast Verification: Deterministic MME
(60E-130E, 10S-30N)

13. The APEC Climate Center
Experimental climate Outlook for Mar-Aug 2010
based on 6-month 1-tier MME Forecasts
Investigators : Doo Young Lee and Hye-In Jeong

14. Launched semi-operationally since late 2008.
Experimental 6-month 1-tier MME Forecast
Launched semi-operationally since late 2008.

15. Model description
CGCM (Tier-1) Models (seasonal 6-month Experimental system)
Institute
Model name
AGCM
Resolution
OGCM
Ensemble Member
APCC
APCC(CCSM3)
CAM3
T85L26
POP1.3
Gx1v3_L40 5
NCEP
GFS
T62 L64
MOM3
1/3o lat x 1o lon L40 15
BOM
POAMA
BAM v3.0d
T47 L17
ACOM2
o latx 2o lon L25 10
FRCGC
SINT(SINTEX-F)
ECHAM4
T106 L19
OPA 8.2
2o cos(lat)x2o lon L31 9
Seoul National Univ.
SUT1
SNU
T42 L21
MOM2.2
1/3o lat x 1o lon L32 6
Univ. of Hawaii
UHT1
T31 L19
UH Ocean
1o lat x 2o lon L2

16. Hindcast Periods & Target Season
Experimental Designs and Data set
Hindcast Periods & Target Season
APCC 6-month climate forecasts are based on 1-tier predictions from 6 institutions in the APEC region
6-month Integration during the period of (23 years)
SCM (6month MME)
: MAMJJA (spring, summer) season started from Feb 1st using CGCM
Simple composite of individual forecast with equal weighting.
Simple Composite Method (SCM):

17. Predicted Niño3 Index
Indian Ocean Dipole mode index
Spatial distributions of forecasted SST Anomalies (SCM) over the tropical Indo-Pacific

18. Hindcast Verification (Niño3 and IOD indices for MAMJJA)

19. APCC
MAM

20. APCC
JJA

21. NCEP
MAM

22. NCEP
JJA

23. POAMA
MAM

24. POAMA
JJA

25. SINT
MAM

26. JJA
SINT

27. SUT1
MAM

28. SUT1
JJA

29. UHT1
MAM

30. UHT1
JJA

31. SCM (Simple Composite Method)
MAM

32. JJA
SCM (Simple Composite Method)

33. Hindcast Verification (Precipitation, Globe)

34. Thank You.